Paging system



Nov. 24, 1970 R. H. MERCER PAGING SYSTEM 15 Sheets-Sheet 1 Filed Feb. 16, 1968 L4 SEC- 3.0 SEC PROPOSED TIMING DIAGRAM INVENTOI? R H MERCER FIG. 2

Nov. 24, 1970 Filed Feb. 16, 1968 FIG.40

TO NUMBER CHECK CKT TO TONE GENERATOR CIRCUIT R. H. MERCER PAGING SYSTEM 15 Sheets-Sheet 5 (Ki/ND INVENTOR R.H.MERCER AGENTS Nov. 24', 1970 Filed Feb. 16.

TO ANN MACH.

AN-I

R. H. MERCER PAGING SYSTEM 5 TC-3 s r Rd ocu-a l5 Sheets-Sheet L TO REGISTER CIRCUIT FlG.5a

\ TO PREFI CIRCUIT TO COMMON CONTROL CKT l L I TO PREF. CIRCUIT TO NUMBER CHECKING CK? FIG4b LCI TO COMMON CONTROL CKT lNVEA/TOR R.H. MERCER AGENTS wdemm R. H. MERCER PAGING SYSTEM Nov. 24, 1970 15 Sheets-Sheet 5 Filed Feb. 16, 1968 l/VVE/VTOI? R.H. MERCER Nov. 24,"'1970 R. H. MERCER 8,5

PAGING SYSTEM Filed Feb. 16, 1968 I 15 Sheets-Sheet 6 TO TRUNK CIRCUIT FIG.4O

V IO (0 h I TO TRUNK v CIRCUIT b FIG. 40 2 TO TRUNK FIG. 5b INVENTOR ClRCUlT R.H.MERCER AGENTS Nov. 24, 1970 Filed Feb. 16', 1968 R. H. MERCER PAGING SYSTEM 15 Sheets-Sheet 9 AGENTS Nov. 24, 1970 R. H. MERCER 3,542,968

PAGING SYSTEM Filed Feb. 16, 1968 15 Sheets-Sheet 11 wtemm 15 Sheets-Sheet 15 To TRUNK CKT 1] ml 0| 0| R. H. MERCER PAGING SYSTEM INVENTO/P R.H. MERCER AGENTS NTUE P5916 mozmwzwo wzok @535 6528 mzok 0 2 m 4 i 0 M. & U. I T l U v 0 5. m 0 25 1mm. l HUM. mo mm w 95m m llo WU EEQ JQEZQQ M28. -5mHU m 054 Emm 5 a 0 Tc C6 6528 20:28 0k C 8 95mm 6528 wzok 0F m m J 9 q. my umtomwtwmvmm mmh omw-wmvm-F Eomw-wmmm m N T 0 N Io mozmmzmw wzok o c w o O .9

Nov. 24, 1970 Filed Feb. 16, 1968 TO TRANSMITTER CONTROL CIRCUIT CONTROL SYSTEM A Patented Nov. 24, 1970 3,542,968 PAGING SYSTEM Ronald H. Mercer, Saint Laurent, Quebec, Canada, as-

signor to The Bell Telephone Co. of Canada, Montreal, Quebec, Canada Filed Feb. 16, 1968, Ser. No. 705,954 Int. Cl. H04m 11/02 US. Cl. 179-41 16 Claims ABSTRACT OF THE DISCLOSURE The paging system, in accordance with the invention, comprises a plurality of trunk circuits for receiving the dial pulses originating from various groups of subscribers and a like number of register circuits connected to the trunk circuits for storing the pulses. A preference circuit is connected to the trunk circuit and comprises a first rotary switch adapted to hunt for any trunk having a complete number stored in it and to connect such trunk to a number checking circuit which determines in which group the number stored in such trunk belongs. The preference circuit also includes a second rotary switch having as many banks as there are groups of calling subscribers, each bank being adapted to select one trunk from each group. A common control circuit energizes the preference circuit to hunt for a trunk having a complete number stored in it and to select one trunk from each group of calling subscribers. The common control circuit also keys a number of transmitters when a number contained in a register circuit has been checked by the number checking circuit and found to exist in one of the various groups of subscribers. In addition, the common control circuit turns on a tone generator circuit when all the transmitters are in operation. Various groups of tone control relays are adapted to be connected to the selected trunk register circuits and operated by the tone generator circuit to convert the dial pulses stored in the register circuit of each selected trunk circuit to corresponding audio tones. The groups of tone control relays are operated successively by the tone generator circuit to transmit each group of audio tones in successive order.

This invention relates to personal paging systems.

A paging system is a one-way communication system from a central location to a person at a remote location. Public address systems have been available for many years but they are limited in range and privacy. Recently, a new concept in paging systems has been developed. Using a radio transmitter, a frequency coded signal is transmitted to one or more receivers each one being tuned to a predetermined frequency. Each person carrying a receiver responds to the receipt of his code by performing a pre-arranged function, such as reporting back to his ofiice.

With this basic concept in mind, many variations of radio paging systems have been developed. For example, one of these systems has been particularly adapted for in-plant paging systems. The in-plant paging system consists essentially of a transmitter and a number of receivers, each of which is assigned a three digit number. When a particular person is required, his code is set up manually, by an operator, on a tone encoder. This device translates each digit of the number into corresponding audio tones. A radio transmitter is keyed, and the audio tones sequentially modulate the carrier signal of the transmitter. This signal is broadcast to all receivers in the plant. Each receiver is equipped with a tone decoder which responds only to the proper sequence of radio tones. When this sequences is detected, an audio oscillator in the receiver is triggered on and an audible signal indicates to the bearer of the receiver that he is being signalled. Also, instead of an audible tone being triggered in the receiver, when the code is received, a light could flash or a combination of lights and tone could be incorporated into one receiver.

Another paging system has been developed for a citywide audience. The philosophy of the system is the same as the above-mentioned in-plant system. However, due to the increased capacity and coverage that was required, a major change in equipment and design was necessary. The city-wide paging system is designed to operate over the regular telephone equipment. A subscriber may be reached by dialing a special central oifice number assigned to the paging system, for example, 251, and a four digit number, for example 1234. The call is routed to the special central office which stores the last four digits in one of a plurality of storage registers until ready for transmission. As the calls enter the registers, a preference circuit selects the numbers in the dialed-in sequence. The register containing the subscribers number is eventually emptied and the number is transferred to an encoding device which translates it into the proper tones. These tones are then sent to one or more radio transmitters for transmission throughout the city. The proper receiver carried by the city-wide paging system customer responds to the coded signals and emits an audio signal. The subscriber who is carrying that receiver is thus alerted to call his office.

It has been found in practice that the above system using a reasonable number of registers, encoders and transmitters can only provide good service to about 1500 subscribers. The number of subscribers on the system is determined by the number of accessible lines to the paging system terminals, the number of storage registers, the total storage time and waiting time for a call to be processed and by the number of users at peak usage periods.

However, the theoretical maximum number of subscribers that the system can accommodate is limited purely by the combination of four digits in a suitable decoder which number has been found to be about 5760 codes with the receivers available on the market.

One method of increasing the number of codes that has been proposed was to increase the number of storage registers, encoders and transmitters. This idea was considered impractical because of the prohibitive cost of setting up the new equipment. Another major disadvantage was that this would necessitate the addition of more channels and this was likely to cause intermodulation problems. Since reliability is a major requirement of the paging system, intermodulation problems must not exist.

The above difiiculties were overcome by a paging system which uses about the same amount of equipment as the original system and operates on only one channel thereby conserving spectrum space. The novel system is based on the idea of trying to squeeze more calls into the pause between transmissions. In the original system, each burst of transmission lasted 1.4 seconds and there was a pause of 2.5 seconds between transmissions. It is proposed to increase the pause between transmissions of the same code to 3.0 seconds and to transmit two other groups of tones or calls in the pause with a slight pause between calls. With such a short pause, however, it is not possible to use identical tones for each group of calls. Consider a call such as 1461 being transmitted right after a call such as 1264. If the two calls have identical tones then it would be possible that receivers responding to codes 2641, 6414, and 4146 be triggered by the two calls. Therefore, the three groups of calls have to have different coded tones.

To satisfy the above requirements, each number assigned to a subscriber is labelled A, B, or C depending on the group assigned to the subscriber. Each digit within a group is assigned a predetermined tone. In addition, corresponding digits in different groups are assigned different tones.

The paging system, in accordance with the invention, comprises a plurality of trunk circuits for receiving the dial pulses designated for various groups of subscribers and a like number of register circuits connected to the trunk circuits for storing the pulses. A preference circuit is connected to the trunk circuit and comprises a first rotary switch adapted to hunt for any trunk having a complete number stored in it and to connect such trunk to a number checking circuit which determines in which group the number stored in such trunk belongs. The preference circuit also includes a second rotary switch having as many banks as there are groups of called subscribers, each bank being adapted to select one trunk from each group. A common control circuit energizes the preference circuit to hunt for a trunk having a complete number stored in it and to select one trunk from each group of called subscribers. The common control circuit also keys a number of transmitters when a number contained in a register circuit has been checked by the number checking circuit and found to exist in one of the various groups of subscribers. In addition, the common control circuit turns on a tone generator circuit when all the transmitters are in operation. Various groups of tone control relays are adapted to be connected to the selected trunk register circuits and operated by the tone generator circuit to convert the dial pulses stored in the register circuit of each selected trunk circuit to corresponding audio tones. The groups of tone control relays are operated successively by the tone generator circuit to transmit each group of audio tones in successive order.

It is also a main feature of the invention to provide a number checking circuit for determining in which group a four digit number stored in a register circuit belongs. The number checking circuit comprises a first and a second crossbar switch each having vertical and horizontal magnets. The vertical and horizontal magnets of the first switch are operated in accordance with the first and the second digits respectively of the number stored. Similarly, the vertical and horizontal magnets of the second switch are operated in accordance with the third and fourth digit of the number stored. Predetermined crosspoints of the first and second switch are connected in series with predetermined relays in accordance with the number and groups assigned to each subscriber whereby the energization of a predetermined one of the relays will determine the group of the called subscriber.

The invention will now be described with reference to the accompanying drawings in which:

FIG. 1 illustrates a timing diagram in accordance with the prior art;

FIG. 2 illustrates a timing diagram in accordance with the invention;

FIG. 3 illustrates a block diagram of the paging system in accordance with the invention;

FIG. 4 illustrates the circuit of the trunk circuit of the paging system;

FIG. 5 illustrates the register circuits;

FIGS. 6 through 9 illustrate the number checking circuit;

'FIG. 10 illustrates the preference circuit;

FIG. 11 illustrates the common control circuit;

FIG. 12 illustrates schematically the tone generator circuit;

FIG. 13 illustrates the tone control relays; and

FIG. 14 illustrates the transmitter control circuit.

As illustrated in FIG. 1, each call of the original system was repeated and had a 1.4 second burst of transmission followed by a 2.5 second pause. In order to increase the capacity of the system, a timing diagram such as illustrated in FIG. 2 is proposed. In such a diagram, the 2.5 second pause is increased to 3.0 seconds and two more calls having 1.4 second bursts of transmission are fit in with a slight pause of say 0.1 second between calls. It is to be understood, however, that the values mentioned above are only illustrative and that other values could be substituted. The diagram of FIG. 2 is not to be taken in a limited sense only as far as it illustrates the idea of squeezing other calls into the pause between subsequent transmissions of the same call.

Each subscriber wishing to have the paging service is given a four digit number as Well as a group number which, in the present disclosed embodiment, will be A, B, or C. As mentioned previously, each group has diflerent coded tones so as to distinguish from the other groups. For example, digit 1 in group A does not have the same tone as digit 1 in group B. In addition, each digit in the same group is assigned a different tone as it is done in the existing paging systems.

The paging system, in accordance with the invention, is shown in block diagram form in FIG. 3. When someone dials the access code, i.e. 251, his line is automatically routed through the Central Office (not shown) to the paging system terminals along special lines called trunk lines 10. The trunk lines 10 are connected to a number of trunk registers 11. Each trunk register 11 accepts the last four dial pulses from the calling subscriber and stores them.

When any trunk register circuit 11 has a complete number stored in it, a preference circuit 12 is energized by a common control circuit 13 to find such trunk and to connect it to a number checking circuit 14. The number checking circuit 14 examines the number stored and determines in which group the dialed number belongs. The number checking circuit 14 then marks the trunk register 11 with a diiferent mark depending on whether the stored number is from the A, B, or C group. If the dialed number has not been assigned to a subscriber then it is rejected and the trunk register is emptied. If the number is valid, the trunk register 11 accepts the marking pulse from the number checking circuit.

The preference circuit 12 is subsequently operated by the common control circuit 13 to select one trunk from each group of called subscribers as determined by the number checking circuit 14.

As soon as a call has been examined by the number checking circuit 14 and found to exist in one of the groups of called subscribers, the common control circuit 13 keys a number of transmitter control circuit 15 connected to transmitters 16. When the transmitters are ready to operate, the transmitter control circuit signal the common control circuit 13 to operate a tone generator circuit 17. Tone generator 17 operates various groups of tone control relays 18 in sequence to convert the information stored in the trunk circuits selected by the preference circuit 12 to corresponding audio tones for transmission by the radio transmitters 16.

The tones are then relayed from the tone generator 17 to the transmitter controls 15 which send the tones along telephone lines to all the transmitters in the network. Then they are broadcast simultaneously throughout the city.

The invention will now be described in detail with reference to FIGS. 4 through 14. The description is divided into various sections referring to the pertinent drawings.

INCOMING TRUNK REGISTER CIRCUIT (a) Trunk circuit-Section l-FIG. 4

When a calling subscriber dials the three digit access code, connection is established to the T, R, & S leads of the trunk circuit. As commonly known in the art, the bridge from the subscriber set operates the line relay L. The line relay L operates the relay R through normally closed contacts SH-l of relay SH and operated contacts L-l of relay L. The operated relay R grounds the.

lock lead LK to the register circuit through contacts R-1 and closes the pulsing lead P to the same register circuit through contacts R2 and contacts L-2 of relay L.

As the calling subscriber dials the four remaining digits of the subscriber being called, relay L releases on each pulse and grounds the lead P over contacts L2 and R-2. This causes the four digits to be stored in the register. A detailed description of the register circuit is given in the following section entitled Register Circuit.

When all four digits have been registered lead DC and DD to the trunk circuit will be grounded by relays in the register circuit as it will be described in the following section. When such is done, the ground on the DC lead operates trunk circuit relay TC. Similarly, ground on the DD lead operates trunk circuit relay SH.

Relay TC, when operated, grounds lead ST through contacts TC-1 and normally closed contacts B-1 of a relay B to be described later. The ST ground is connected over the winding of relay DC1 to lead DC1 and through diode D to lead CST. The DC1 and the CST leads are connected to the Preference Circuit and the Common Control Circuit respectively described in the following sections. For the purpose of the description of the present section, let us say that the preference circuit will start hunting upon application of ground to the CST lead and find the trunk which is causing the CST lead to be grounded. Furthermore, the Preference Circuit will provide battery to operate relay DC1 of that trunk.

Relay SH when operated locks operated over contacts SH2 and under control of relay L through contacts L-l. Relay SH also operates relay AN through contacts SH-3 and closed contacts TC-4, and relay DC through contacts SH-4. In addition, relay SH opens the operate path of relay R by opening contacts SH-l. Relay R remains operated, however, over its own contacts R-3, operated contacts DC-l of relay and released contacts TC1-2 of trunk circuit relay TC1. Finally, relay SH grounds the sleeve lead S towards central ofiice through contacts CH-S.

Relay AN when operated connects the announcement machine to the T and R leads through contacts AN-l and connects the ST1 lead to the STZ lead starting the announcement machine through contacts AN-2. The announcement machine provides a recorded message to the paging system subscriber to the efiect that the called number has been stored and will be processed in due course.

Relay DC when operated locks operated under the control of contacts TC-2 of operated relay TC, and closes the locking path for relay R through contacts DC1 and TC1-2 as mentioned previously.

The operation of relay DC1 closes contacts DC1-1 and connects the A, B, C & D leads of the register circuit (shown in block diagram in FIG. 4) to the PA, PE, FC & FD lead of the number checking circuit respec tively. It also completes paths KA, KB or KC to the number checking circuit through contacts DC1-2A, DC1-2B or DC1-2C. The number checking circuit is described fully in Section 3. For the purpose of the description of this section, let us say that the number checking circuit will determine into which group (A, B or C) the particular number which has been stored in the trunk register under test belongs. Governed by this finding, the number checking circuit will place a momentary ground on leads KA, KB or KC.

The momentary ground placed on leads KA, KB or KC triggers silicon controlled switch SCRA, SCRB or SCRC through contacts DC12A, DC1-2B or DC1-2C, and operates the appropriate KA, KB or KC relay. Relays KA, KB and KC receive battery from leads LAI, LB1 and LCI connected to the common control circuit which will be explained later. Relay B also operates in series with whichever of the three KA, KB or KC relays was selected. Because of the locking action of the SCR switches, such relays lock operated under the control of contacts R-1 of relay -R. The operation of relay B opens contacts B-1 and opens the ST lead to the CST diode and the DC1 relay.

The release of the relay DC1 disconnects the trunk from the number checking circuit and renders the number checking circuit free to check other trunk circuits which have a complete four digit number stored if any such trunks exist.

The energization of relay KA, KB or KC ope-rates contacts KA(10), KB(10) or (KC(1-0) and directs the register circuit output to the correct group (A, B or C) of tone control relays. The operation of relay KA, KB or KC also connects the winding of relay P to HA, HB or HC lead of the Preference Circuit through KA-ll, KB-ll or KC-ll. As will be described later, when an appropriate space becomes available, the preference circuit will apply ground on lead HA, HB or HC. Relay P will operate and lock operated to the ground on lead LK from closed contacts R-1 of relay R and its own contacts P1. Relay P and relay KA, KB or' KC will also connect the winding of the TC1 relay to the CTA, CTB or CTC lead to the common control circuit through contacts P-2 and KA-12, KB-12 or KC12, respectively.

When the common control system is ready to transmit the group of codes involved (A, B or C) ground will be supplied to the CT A, CTB or CTC lead as will be explained later. The ground on CTA, CTB or CTC will operate trunk circuit relay TC1. The operation of relay TC1 closes the A, B, C and D leads through to the tone generator circuit in closing contacts TC-1. The operation of relay TC1 opens contacts TC1*2 and releases relay R. In addition, it supplies locking ground to lead LK at contacts TC1-3 in place of that supplied by contacts R-1 of relay R.

The release of relay R opens the pulsing lead P to the register circuit at contacts R-2. In addition, it removes ground from the LK lead. This removal has no elfect at this time, however, since ground is also supplied by operated relay TC1 at contacts TC1-3.

When the code has been transmitted the correct number of times, the common control circuit will remove the ground on lead CTA, CTB or CTC thus causing the TC1 relay to release. The release of relay TC1 will open the lead LK at contacts TC1-3 and restore all register circuit relays and relay P of that trunk.

The release of the register circuit relays will remove ground from leads DC and release relay TC. It will also remove ground from lead DD and release relay SH unless the calling subscriber has not hung up. If the calling subscriber has not hung up, the release of relay TC will operate relay SS through released contacts TC-3 and operate contacts SH6.

The operation of relay SS opens contacts SS-1 removing ground from the sleeve lead S. It also operates relay SS1 which is slow to operate through contacts SS-Z. The operation of relay SS1 places ground on the sleeve lead through contacts SS11. The operation of the SS relay and the SS1 relay provides a Wink action on the sleeve lead which will release the calling subscriber from the circuit. The ground will be held on the sleeve lead after the wink until all trunk circuit relays have released as follows:

The release of relay TC opens contacts TC-4 and releases relay AN. In addition, the release of relay TC opens contacts TC-2 and TC-S and releases relay DC if relay SH is released.

When the T and R leads are opened from the central ofiice (calling party hung up), the relay L will release in the usual fashion. The release of relay L opens contacts L-l and releases relay SH. The release of relay SH opens contacts SH-4 and releases relay DC (if relay TC is released). The release of relay SH also opens contacts SH-6 and releases relay SS. The release of relay SS opens contacts 88-2 and releases SS1. The release of relay SS1 removes ground form sleeve lead S and allows the trunk circuit to be seized by another calling party.

There are conditions under which subscribers are disconnected from the trunk circuit, such conditions being as follows:

(A) If subscriber disconnects before the code has been transmitted.The above sequence of operation of relay SS and SS1 applies when the L relay is released by subscriber disconnect.

(B) I f subscriber fails to dial after seizing tr1mk.-The relay L is operated closing contacts L-l and operating relay R. The operation of relay R supplies ground for timeout relay RL through closed contacts RA-3, FIG. (to be described later), R-3, SH1 and L-l. After a timeout of 30 seconds the RL relay operates. The operation of relay RL closed contact-s RL-l and starts the SS and SS1 relay sequence described above to provide a wink condition on the sleeve. The calling subscriber is disconnected releasing the L relay. The release of relay L releases the R relay which releases the RL relay through contacts R-3. The release of relay RL releases relays SS. The release of relay SS releases SS1 as above and causes the trunk circuit to be released.

(C) If subscriber dials one to three digits.A timeout feature will operate under control of a relay RA in the register circuit. The relay RA operates while each digit is dialed so that if a subscriber hesitates too long between digits, contacts RA-3, FIG. 5 will be closed long enough to operate relay RL and a disconnect will follow as indicated in (B).

If a number stored in the register circuit is found not to exist in the number checking circuit, a momentary ground will be placed by the number checking circuit (to be described later) on lead R]. The ground on the R] lead operates relay TC1 through contacts DC13 of relay DC1. The operation of relay TC1 will release relay R by opening contacts TC1-2. It will also ground the lead LK at contacts TC1-3 thus holding all relays which were previously held by relay R. When the RI ground is removed, relay TC1 will release opening contacts DC1-3 and ground will be removed from lead LK at contacts TC1-3 thus releasing all relays in the trunk and register circuit and returning the trunk circuit to an idle condition.

(b) Register Circuit-Section 2--FIG. 5

When the pulsing relay L in the trunk circuit operates, the relay R in the trunk circuit operates. The R relay operated grounds the LK lead and grounds the sleeve lead S of the trunk as mentioned previously. In addition, it provides a path between contacts L2 of the L relay and the P lead. The R relay is slow to release and does not release during pulsing.

For each pulse, the pulsing relay in the trunk circuit releases and momentarily grounds the P lead. The first pulse operates a relay P1 through normally closed contacts Dl, PZ-l and P3-2. The operation of relay P1 closes contacts P1-1 and operates a register advance relay RA. In addition, relay Pl, through its own contacts P1-2, contacts RA-l of relay RA and normally closed contacts DZ closes a locking path for itself in series with the winding of a relay P2.

Relay P2 remains short circuited by the ground on the P lead. At the end of the pulse when this ground is removed, relay P2 is operated. The second pulse operates relay P3 through contacts P2-2 of relay P2. Relay P3 locks operated through its own contacts P3-1, and releases relays P1 and P2 by opening its contacts P3-2. At the end of the pulse relay P3 releases. The next pulse starts a repeat of this cycle. Thus, at the end of an odd number of pulses the P1 and the -P2 relays remain operated. At the end of an even number of pulses, the P1, P2, and P3 relays are all released.

The operation of relay P1, as mentioned previously, operates a path for relay RA at contacts P1-1. This path is opened at the end of the first pulse by the operation of relay P2 which opens its contacts P2-3. Relay P3 closes the operate path of relay RA at contacts P3-3' during the second digit. Thus, the operate path for the RA relay is closed during a pulse, and opened between pulses. Relay RA is slow releasing and remains operated between the pulses of each digit, but releases between digits.

With register advance relay RA operated, ground is supplied to contacts P1-3 to operate the storage relays A1 to A6. The first operation of relay P1 grounds the ODD lead through contacts RA-l and normally closed contacts D-Z of relay D to be described later. The first operation of relay P1 grounds the ODD lead to operate relay A1 through closed contacts A-1, B-1 and C-1 of steering relays A, B and C and closed contacts A4-1, A2-1, A34 and A5-1. Relay A1 locks operated through contacts Al-l, A2-2, A3-1, A4-2, A5-2 and ground on lead LK from the trunk circuit. The first release of relay P1 on the second pulse closes contacts P1-3 and grounds the EVEN lead operating relay A2 through contacts C-2, B2, A4, A1-2. Relay -A2 looks through contacts A2-3, A3-1, A42, A5-2 and ground on lead LK. In addition, the operation of relay A2 releases relay A1 at contacts A22. The second operation of relay P1 grounds the ODD lead to operate relay A-3 through now closed contacts A2-4. Relay A-3 locks itself to the LK ground through contacts A3-2. The second release of relay P1, on the second pulse, grounds the EVEN lead operating relay A4 through now closed contacts A3-3. Relay A4 locks itself through contacts A4-3. The operation of relay A4 also opens contacts A4-2 and releases A3. Subsequent pulses operate and release the storage relays as follows:

When any one of relay A1 through A5 is operated, contacts A1-5, A2-5, A3-5, A4-5, or AS-S is closed and a path is completed over the released contacts RA-2 of relay RA and normally closed contacts D-3, (3-3, B-3 and A-3 to steering relay A. When relay A is operated, it locks operated to ground on lead LK through contacts A-4 and closed contacts B-4, D4 and D4 of steering relays B, C, and D. The operation of relay A opens contacts A1 and A-2 and closes contacts A-S to transfer thie even and odd pulsing leads to the B group of storage re ays.

The B group of storage relays functions the same as the A group described previously and when the RA relay releases after the last pulse of the second digit, steering relay B operates over contacts B1-5, B25, B3-5, B4-5 or B5-5 and closed contacts A-6, B3, C3, D-3 and RA2. The operation of steering relay B releases relay A at contacts B4 and transfers the even and odd pulsing leads of the C group of storage relays by opening contacts B-1 and B-2 and closing contacts B-S. Relay B locks operated through contacts B-7, C4, D4 and ground lead LK.

The C group of storage relays operates the same as the A and B groups described previously and upon storing the last pulse of the third digit will cause steering relay C to operate. The operation of steering relay C releases relay B at contacts C-4 and transfers the even and odd pulsing leads to the D group of storage relays by opening contacts C-1 and C-2 and closing contacts C-S. Relay 1C lgclljls operated through contacts C-7 and D4 to ground The D group of storage relays operates the same as the A, B and C groups discussed previously. Upon storage of the last pulse of the fourth digit steering relay D will operate. The operation of steering relay D releases relay C at contacts D-4. Relay D locks operated to the LK lead through contacts D7. The operation of relay D also disconnects the operate ground to the storage relay ground at contacts D-l, D-2 and D-3 so that any additional digits dialed does not affect the number which has been stored. In addition, the operation of relay D grounds the DC and DD lead at contacts D-8 and D-9 to operate relays TC and SH respectively in the trunk circuit.

The A1-A6, B1436, C1-C6 and D1-D6 storage relays connect the A, B, C and D leads respectively to one of leads 1 to 9 depending on the particular storage relays operated as covered in the table on page 15. For example, if digits 1243 are dialed relays A1, B2, C3 and D4 are operated and contacts A1-6, B2-6, C3-6 and D4-6 are closed. Consequently, leads A, B, C and D are connected to leads 1, 2, 3 and 4. The A, B, C and D leads are opened in the trunk circuit FIG. 4 at contacts TC1-1 until connection has been established by the Common Control Circuit. When preference has been established in the Preference Circuit, to be described later, relay TC1 will be energized by the Common Control Circuit to close contacts TC11 in the trunk circuit to connect leads A, B, C and D to the Tone Generator Circuit.

When the code has been transmitted the LK lead will be opened, as mentioned previously, releasing all relays which have locked operated in the register circuit.

NUMBER CHECKING CIRCUIT-SECTION 3 FIGS. 6, 7, 8 AND 9 When any trunk circuit has a complete four digit number stored, the CST lead, FIG. 4, is grounded by the operation of relay TC which is operated by the register circuit. The grounded CST lead starts the operation of the Preference Circuit as mentioned previously and as will be described fully in the following section. When the trunk has been found by the Preference Circuit the Common Control Circuit provides a ground on lead MST FIG. 6. The ground on lead MST operates relay MST in the number checking circuit through closed contacts RJ1, SC-l, SB-1 and SA-l.

The operation of relay MST connects ground and battery to unijunction transistor oscillator Q501 FIG. 6 through contacts MST-1 and MST-2 respectively and removes the shunt around capacitor C501 through contacts MST-4. The operation of relay MST also connects battery to lead H of the crossbar switches #1 and #2 in FIGS. 7 and 8 through contacts MST-3. The unijunction transistor operates in a manner known in the art to generate a series of pulses the shape and spacing of which are controlled by resistor R-501 and capacitor C-501.

The first pulse generated by oscillator Q501 operates relay RLY which closes contacts RLY-1 to operate relay PA through normally closed contacts PA-4, diode D1, normally closed contacts PC- and closed contacts MST- 2. The operation of relay PA closes contacts PA-1 and provides ground to lead OA of crossbar switch #1 FIG. 7. Relay PA locks operated through its own contacts PA-2 under the control of contacts PC-tl of relay PC. Relay PA also closes contacts PA-3 and provides a positive potential source to lead FA of the trunk circuit FIG. 4. The positive potential is routed over the register circuit contacts of relays A1-A6 to the coils of crossbar switch #1. The polarity of diodes D1-D20 in series with the windings of these coils is such that only the vertical magnets S1-S0 of the switch could be operated. Consequently, a vertical magnet of switch #1 corresponding numerically to the first digit which was stored in the register circuit operates.

The second pulse from pulse generator Q501 operates relay PB through now closed contacts PA-S of relay PA.

The operation of relay PB closes contacts PB-l and applies ground on lead OB of switch #1 FIG. 7. Relay PB locks operated through its own contacts PB-Z. The operation of relay PB also provides a negative potential source through contacts PB-3 to lead FB going to the trunk circuit. The negative potential will be routed over the contacts of relays B1-B6 of the register circuit to the coils of crossbar switch #1. The polarity of the diodes D1- D20 in series with each coil is now such that only the horizontal magnets Hl-HO could be operated. Consequently, a horizontal magnet of the first switch corresponding numerically to the second digit stored in the register operates. The crosspoints of crossbar switch #1 corresponding to the first two digits stored in the register lock operated through their own contacts H(10)4 and H(1 0)1 under the control of contacts MST-3 of relay MST.

The third pulse from oscillator Q501, operates relay PC through contacts PB-S. The operation of relay PC opens contacts PC-O and releases relays PA and PB. Re lay PC locks operated through its own contacts PC-2. Relay PC also provides ground to lead 0C for crossbar switch #2 FIG. 8 through contacts PC-l. In addition, relay PC provides a positive potential to lead PC of the trunk circuit through contacts PC3. The positive potential is routed over contacts of relays C1C6 of the register circuit to the coils of crossbar switch #2. The polarity of diodes D1-D20 of crossbar switch #2 is such that only the vertical magnets Sl-SO of that switch could be operated. Consequently, the vertical magnet corresponding numerically to the third digit stored in the register circuit is operated.

The fourth pulse from oscillator Q501 operates relay PD through contacts PC-4. Relay PD closes contacts PD-l and provides a ground to lead OD FIG. 8. Relay PD locks operated through its own contacts PD-2. In addition, relay PD closes contacts PD3 and provides a negative potential to the FD lead of the trunk circuit. The negative potential is routed over contacts of relays D1- D6 of the register circuit to crossbar switch #2. The polarity of diodes Dl-D20 is such that only the horizontal magnets H1-H0 could be operated. Consequently, the horizontal magnet corresponding numerically to he digit stored in the register circuit is operated. Crosspoints of crossbar switch #2 which correspond numerically to the third and fourth digits stored in the register circuit lock operated through their own contacts H(1-0)-4 and H(10)-1 under the control of contacts MST-3 of relay MST.

At this time, crossbar switches #1 and #2 have been set up to correspond with the four digit number stored in the register circuit. If a diode D- is wired between the pair of crosspoints involved such as shown in FIG. 9, a path exists from the input of crossbar #1 and the output of crossbar #2. Switch #2 has three wire crosspoints and depending on which wire has been connected to the D- diode, one of relays SA, SB or SC operates. The operated relay SA, SB or SC closes contacts SA-2, SB-2 or SC2 and grounds lead KA, KB or KC. The ground on lead KA, KB or KC marks the trunk register circuit FIG. 4 as containing a number requiring A, B or C coding. In the system illustrated in FIG. 9, diode D 1456A, for example, has been wired between crosspoints 1-4 and 5-6 corresponding to digits 1456 stored in the register. Since diode D-1456A is connected to wire A of switch #2, relay SA is operated and closes contacts SA-Z to ground lead KA. The ground on lead KA marks the trunk register circuit under test as containing a number requiring A coding. The operation of relays SA, SB or SC opens contacts SA-l, SB-l or SC1 to deenergize relay MST and release the number checking circuit.

Any four digit number which has been stored in a register but for which no diode has been provided (b tween crossbar #1 and crossbar #2) will not receive such a marking pulse and consequently, will not proceed 

